Arnold Horwitz

XOMA 052, a potent, high-affinity monoclonal antibody for the treatment of IL-1β-mediated diseases

Interleukin-1β (IL-1β) is a potent mediator of inflammatory responses and plays a role in the differentiation of a number of lymphoid cells. In several inflammatory and autoimmune diseases, serum levels of IL-1β are elevated and correlate with disease development and severity. The central role of the IL-1 pathway in several diseases has been validated by inhibitors currently in clinical development or approved by the FDA. However, the need to effectively modulate IL-1β-mediated local inflammation with the systemic delivery of an efficacious, safe and convenient drug still exists. To meet these challenges, we developed XOMA 052 (gevokizumab), a potent anti-IL-1β neutralizing antibody that was designed in silico and humanized using Human Engineering™ technology. XOMA 052 has a 300 femtomolar binding affinity for human IL-1β and an in vitro potency in the low picomolar range. XOMA 052 binds to a unique IL-1β epitope where residues critical for binding have been identified. We have previously reported that XOMA 052 is efficacious in vivo in a diet-induced obesity mouse model thought to be driven by low levels of chronic inflammation. We report here that XOMA 052 also reduces acute inflammation in vivo, neutralizing the effect of exogenously administered human IL-1β and blocking peritonitis in a mouse model of acute gout. Based on its high potency, novel mechanism of action, long half-life, and high affinity, XOMA 052 provides a new strategy for the treatment of a number of inflammatory, autoimmune and metabolic diseases in which the role of IL-1β is central to pathogenesis.

Chimeric mouse-human anti-carcinoma antibodies that mediate different anti-tumor cell biological activities

Two chimeric mouse-human antibodies, ING-1 (IgG1, kappa) and ING-2 (IgG1, lambda), have been constructed starting from anticarcinoma mouse hybridomas. These antibodies bind to different tumor-associated antigens which are present on human breast carcinoma cell lines at 10(5)-10(6) antigens/cell; ING-1 binds to a 40-kD membrane glycoprotein, while ING-2 binds to a glycoprotein of greater than 300 kD. In competitive binding experiments, both chimeric antibodies have identical binding activity to the parental mouse antibodies. The antibody-dependent cellular cytotoxicity (ADCC) and complement-dependent cytolysis (CDC) activities of these antibodies were studied on carcinoma target cell lines. ING-1 mediates potent ADCC, but ING-2 had undetectable or very weak ADCC activity. ING-2 ADCC activity was significantly reduced by the addition of human serum, but ING-1 ADCC was unaffected. Neither ING-1 nor ING-2 mediated CDC of breast carcinoma cell lines, but ING-1 mediated CDC of a colon carcinoma cell line. ING-1 antibody-antigen complexes are stable on the target cell surface for at least 2 hours, while much of bound ING-2 is lost from the surface of cells due to internalization or shedding. The activities of these antibodies confirm that the target antigen plays an important role in the biological effector functions triggered by cell-surface-bound antibodies. Both of these chimeric antibodies are candidates for further study as immunoconjugates for cancer diagnosis or therapy, and the unconjugated ING-1 antibody has promise for cancer therapy due to its potent activation of ADCC.

Kinetic Approach to Pathway Attenuation Using XOMA 052, a Regulatory Therapeutic Antibody That Modulates Interleukin-1β Activity

Many therapeutic antibodies act as antagonists to competitively block cellular signaling pathways. We describe here an approach for the therapeutic use of monoclonal antibodies based on context-dependent attenuation to reduce pathologically high activity while allowing homeostatic signaling in biologically important pathways. Such attenuation is achieved by modulating the kinetics of a ligand binding to its various receptors and regulatory proteins rather than by complete blockade of signaling pathways. The anti-interleukin-1β (IL-1β) antibody XOMA 052 is a potent inhibitor of IL-1β activity that reduces the affinity of IL-1β for its signaling receptor and co-receptor but not for its decoy and soluble inhibitory receptors. This mechanism shifts the effective dose response of the cytokine so that the potency of IL-1β bound by XOMA 052 is 20–100-fold lower than that of IL-1β in the absence of antibody in a variety of in vitro cell-based assays. We propose that by decreasing potency of IL-1β while allowing binding to its clearance and inhibitory receptors, XOMA 052 treatment will attenuate IL-1β activity in concert with endogenous regulatory mechanisms. Furthermore, the ability to bind the decoy receptor may reduce the potential for accumulation of antibody·target complexes. Regulatory antibodies like XOMA 052, which selectively modulate signaling pathways, may represent a new mechanistic class of therapeutic antibodies.

In Vitro and In Vivo Pharmacology and Pharmacokinetics of a Human Engineered™ Monoclonal Antibody to Epithelial Cell Adhesion Molecule

ING-1(heMAb), a Human Engineered monoclonal antibody to epithelial cell adhesion molecule (Ep-CAM), was evaluated for its in vitro and in vivo activity. The dissociation constant of ING-1(heMAb) for binding to Ep-CAM on HT-29 human colon tumor cells was 2 to 5 nM, similar to chimeric ING-1. In antibody-dependent cellular cytotoxicity and complement-dependent cytotoxicity assays, ING-1(heMAb) caused a concentration-dependent lysis of BT-20 breast, MCF-7 breast, HT-29 colon, and CACO-2 colon tumor cells, with maximum cytolysis at approximately 1 microg/ml. After an intravenous injection in rats, plasma ING-1(heMAb) levels declined with an alpha half-life of 8 to 11 hours, and a beta half-life of 20 days, typical of an IgG in a species without the target for ING-1. In nude mice with human HT-29 colon tumors, plasma ING-1(heMAb) levels declined more rapidly than in non-tumor-bearing mice, suggesting an enhanced clearance via the tumor-associated human Ep-CAM. In nude mice, intravenous treatments with ING-1(heMAb) twice a week for 3 weeks significantly suppressed the growth of human HT-29 colon and PC-3 prostate tumors in a dose-dependent manner, with 1.0 mg/kg providing the greatest benefit. These results indicate that Human Engineered ING-1(heMAb) is a high-affinity antibody with potent in vitro activity that targets and suppresses the growth of human tumors in vivo.

Chimeric immunoglobulin light chains are secreted at different levels : influence of framework-1 amino acids

Immunoglobulin light chain proteins are generally thought to be readily secreted without their corresponding heavy chains; non-secreted light chains have been viewed as aberrant forms. We have re-examined this assumption by expressing chimeric mouse-human light chains constructed for 12 mouse antibodies (mouse variable regions fused to a human kappa light chain constant region) in Sp2/0 and CHO cells. Five of the 12 light chains were either poorly secreted or not secreted at all. There was approximately a five-fold difference in the levels of secreted light chain between the highest poor secretor and the lowest good secretor. All of these light chains formed functional chimeric IgGs, which were secreted at similar levels, when co-expressed with their respective chimeric mouse-human heavy chains (mouse variable regions fused to a human gamma-1 heavy chain constant region). The influence of variable region amino acids on light chain secretion was examined by replacing the Framework-1 region of three poorly-secreted chimeric light chains with that of a readily-secreted light chain. For two of the light chains, secretion levels increased approximately 30- and 100-fold relative to that of the unmodified light chains. Comparison of the Framework-I amino acid sequence of the poorly- and readily-secreted light chains revealed an asparagine (N) and proline (P) at positions 11 and 12, respectively of these poorly-secreted light chains and a leucine (L) and serine (S) in the same region for some of the readily secreted light chains. Alteration of the NP to LS for one of the poorly-secreted light chains resulted in an approximately seven-fold increase in light chain secretion over that of the native form of the poorly-secreted light chain. We conclude from these studies that poor secretion can be a naturally occurring state for normal light chains and that amino acids within Framework-1 contribute to poor secretion for some of the light chains.

Enhancement of antibody fragment secretion into the Escherichia coli periplasm by co-expression with the peptidyl prolyl isomerase, FkpA, in the cytoplasm

Improper protein folding or aggregation can frequently be responsible for low expression and poor functional activity of antibody fragments secreted into the Escherichia coli periplasm. Expression issues also can affect selection of antibody candidates from phage libraries, since antibody fragments displayed on phage also are secreted into the E. coli periplasm. To improve secretion of properly folded antibody fragments into the periplasm, we have developed a novel approach that involves co-expressing the antibody fragments with the peptidyl prolyl cis-trans isomerase, FkpA, lacking its signal sequence (cytFkpA) which consequently is expressed in the E. coli cytosol. Cytoplasmic expression of cytFkpA improved secretion of functional Fab fragments into the periplasm, exceeding even the benefits from co-expressing Fab fragments with native, FkpA localized in the periplasm. In addition, panning and subsequent screening of large Fab and scFv naïve phage libraries in the presence of cytFkpA significantly increased the number of unique clones selected, as well as their functional expression levels and diversity.

rBPI(10—193) is secreted by CHO cells and retains the activity of rBPI21

rBPI23, a recombinant N-terminal fragment of human bactericidal/permeability-increasing protein (BPI), kills Gram-negative bacteria and neutralizes endotoxin. rBPI 21, a variant in which cysteine 132 is changed to alanine, retains the activities of rBPI23. Analysis of certain purified rBPI 21 preparations revealed that some of the molecules had lost nine amino acids from the amino terminus. To explore the effect of this modification on structure and activity, we cloned and expressed a variant of rBPI 21, designated rBPI(10-193), which lacks the first nine amino acids. A monoclonal antibody believed to recognize the amino terminus of rBPI 21 cross-reacted with rBPI21, but not with rBPI(10-193) or full length recombinant BPI (rBPI). These results demonstrated that the antibody recognizes the first nine amino acids of rBPI21 and that this region of the holoprotein (rBPI) is inaccessible to the antibody (as suggested by the known 3-D structure). Purified rBPI(10193) and rBPI 21 were similarly potent in in vitro assays measuring bactericidal, endotoxin binding and neutralization activities. In a mouse model of lethal bacteremia, rBPI(10-193) and rBPI21 were similarly potent whereas in a mouse endotoxin challenge model, rBPI(10-193) appeared to be at least 2-fold more potent than rBPI21. In conscious rats, a rapid bolus dose of 40 mg/kg of rBPI21 caused a significant transient decrease in blood pressure while the same dose of rBPI(10-193) caused no blood pressure decrease. We conclude from these studies that the first nine amino acids of rBPI21 are not essential for the anti-infective and endotoxin-neutralizing activities of BPI.

An Allosteric Antibody to the Leptin Receptor Reduces Body Weight and Reverses the Diabetic Phenotype in the Lepob/Lepob Mouse

Leptin (LEP) deficiency results in major metabolic perturbations, including obesity, dyslipidemia, and diabetes. Although LEP deficiency can be treated with daily injections of a recombinant LEP, generation of an antibody activating the LEP receptor (LEPR) that has both an intrinsically long half‐life and low immunogenicity could be useful in the treatment of this condition.

Antibody engineering to improve manufacturability

Expression variation among antibodies produced by stably transfected Chinese Hamster Ovary (CHO) cells is well established. While developing CHO-K1 cell lines, we encountered a human monoclonal antibody, mAb B-c, with severe manufacturability issues, including very poor expression and high levels of heavy chain (HC) dimer and high molecular weight aggregates. Using transient expression in CHO-K1 cells, we identified light chain (LC) as the source of the manufacturability issues for this antibody. While other antibodies achieved optimal expression at 1:1 or 2:1 LC to HC ratios, mAb B-c required up to a 6:1 LC:HC for maximal expression, which was still significantly lower than that for other tested antibodies. To overcome the manufacturability issues, LC shuffling was performed with the original HC to select antibodies with unique LCs which retained acceptable binding affinities. Transient CHO-K1 expression evaluation of the new LCs co-expressed with the original HC identified antibodies with high expression at a 1:1 or 2:1 LC:HC; the expression levels of these new antibodies were comparable to those of other well-expressed antibodies. Expression of these new antibodies in stably transfected CHO-K1 cells confirmed these results. In addition, antibodies containing the new LCs had very low levels of high molecular weight aggregates and HC dimer. These results demonstrate that certain antibody manufacturability issues can be attributed to LC and that engineering antibodies by pairing HCs with alternate LCs can improve antibody expression and product quality while maintaining or improving affinity.